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1	Effect of Microstructure on the Fatigue Behavior of Type 304L Stainless Steel including Mean Strain and Cyclic Rate Effects Pegues, Jonathan W 09 December 2016 (has links) In this study, the effects of stress and strain rate on cyclic deformation, secondary hardening, martensitic phase transformation, crack initiation, and fatigue behavior of type 304L stainless steel are examined. A series of load and strain controlled uniaxial zero and non-zero mean strain fatigue tests were conducted with varying frequencies in order to investigate the effect of loading rate on fatigue behavior. The volume fraction of martensite was quantified for several tests using x-ray diffraction and electron backscatter diffraction. The loading rates were found to have a direct effect on the microstructure and fatigue behavior of the alloy investigated. Adiabatic heating from an increased rate of loading was found to effect martensite formation which is a major contributor to the secondary hardening phenomena associated with many austenitic stainless steels under cyclic loading. Also affected by the microstructural changes were cyclic deformation, crack initiation, microstructurally small crack growth, and fatigue behavior. crack initiation transformation fatigue behavior 304L stainless steel martensite
2	Two Dimensional Friction Stir Welding Model with Experimental Validation Owen, Charles Blake 15 March 2006 (has links) (PDF) The performance of a coupled viscoplastic model of FSW has been evaluated over a variety of tool RPMs and feed rates. Initial results suggested that further optimization of the material parameters and an additional ability to model the thermal recovery of the material would improve the overall performance of the model. Therefore, an experimental/numeric approach was taken to improve and quantitatively compare the performance of the model based upon the thermal profile of the workpiece. First, an experimental method for obtaining real-time temperature measurements during Friction Stir Processing (FSP) of 304L Stainless Steel was developed. The focus of the method was to ensure that the obtained temperatures were both accurate and repeatable. The method was then used to obtain thermal cycle data from nine welds, each at different operating conditions ranging in tool rotational speed from 300 to 500 RPMs and in feed rate from 0.85 to 2.54 mm/s (2 - 6 in/min). Then a family of nine numerical models was created, each model corresponding to one welding condition. The performance due to improved convergence stability and the added thermal recovery term are also discussed. A gradient following technique was used to optimization and iteratively adjust nine material parameters to minimize the difference between the numerical and experimental temperature for the whole family of models. The optimization decreased the squared error between the numerical and measured temperatures by 76%. Recommendations are also made that may allow the optimization method to return greater dividends. friction stir welding 304L stainless steel numerical modeling Mechanical Engineering
3	Residual stress effects on the fracture toughness behaviour of a narrow-gap austenitic stainless steel pipe weld McCluskey, Robert January 2012 (has links) Automated narrow-gap girth-butt welds are replacing conventional welding methods to join sections of austenitic stainless steel pipe in the primary circuit of Pressurised Water Reactors, to reduce manufacturing costs and improve quality. To ensure the safe operation of these systems, reliable structural integrity assessments have to be undertaken, requiring the mechanical properties of welded joints to be characterised alongside the weld residual stress magnitude and distribution.This research project characterised, for the first time, the weld residual stress field and the tensile and ductile fracture toughness properties of a 33 mm thick narrow-gap 304L stainless steel pipe weld. The residual stress was characterised using two complementary approaches: deep hole drilling and neutron diffraction. A novel neutron diffraction scanning technique was developed to characterise the residual stress field, without cutting an access window into the component, leaving the original weld residual stress field undisturbed. A modified deep hole drilling technique was developed to characterise the residual stress retained in fracture mechanics specimens extracted from the pipe weld in two orientations. The modified technique was shown to measure the original weld residual stress field more accurately than through conventional deep hole drilling. Residual stresses, exceeding 50% of the weld material proof strength, were retained in axially-orientated fracture mechanics specimens.Tensile tests showed that the weld was approximately 60% overmatched. It was demonstrated that neither retained residual stress, nor specimen orientation, had a discernible effect on the measured fracture toughness of the weld material. In less ductile materials, however, the level of retained residual stress may unduly influence the measurement of fracture toughness. At initiation, the fracture toughness properties of both the parent and weld materials were far in excess of the measuring capacity of the largest fracture mechanics specimens that could be machined from the weld.The influence of residual stress and fracture toughness on the performance of narrow-gap welded pipework was investigated. Full elastic-plastic finite element analyses were used to model the pipe weld, containing a postulated defect under combined primary and secondary loading. The results, applied within the framework of an R6 structural integrity assessment, compared different plasticity interaction parameters on the prediction of failure load; the conventional ρ-parameter approach was compared with the recently developed, more advanced, g-parameter. It was shown that the g-parameter significantly reduced the conservatism of the ρ-parameter approach. However, for this pipe weld, plastic collapse was predicted to precede failure by ductile initiation, suggesting that a plastic collapse solution may be an appropriate failure criterion to use in structural integrity assessments of similar component and defect combinations. 623.8
4	Controlled chloride cracking of austenitic stainless steel Raseroka, Mantsaye Sophie 03 July 2009 (has links) Type 304 stainless steel is used in various applications where corrosion resistance is required. This material is selected for weldability and corrosion resistance, but it can suffer stress corrosion cracking (scc), corrosion fatigue, pitting and crevice corrosion in chloride environments. The aim of this project was to produce Type 304 containers with intentional stress corrosion cracks, to serve as test samples for future weld repair trials. A test rig was constructed which used thermal stress to crack Type 304 tube samples; a central Type 310 stainless steel bar contained a heating element, so that the bar serve as a heat source and a stressing element. The rig was filled or half filled with magnesium chloride solution. The elastic strain in the tube sample was directly related to the temperature difference between the central bar and the sample. The thermal stress was sufficient to cause stress corrosion cracking. The tests were terminated when the first crack extended through the wall thickness of the 304 tube sample. The distribution and depth of cracks were determined after the tests. The test procedure caused the formation of multiple cracks in the tube sample. The temperature controller caused cyclical variation in the bar temperature and hence in the thermal stress. However, the temperature variation did not have an effect on cracking; corrosion fatigue did not contribute to cracking, and the cracks had the classic branched transgranular morphology of chloride cracking. Copyright / Dissertation (MSc)--University of Pretoria, 2009. / Materials Science and Metallurgical Engineering / unrestricted Temperature Scc Chloride stress corrosion cracking Austenitic stainless steel Strain Corrosion fatigue Type 304l stainless steel Crack density UCTD
5	Friction Stir Welding and Microstructure Simulation of HSLA-65 and Austenitic Stainless Steel Failla, David Michael, II 08 September 2009 (has links) No description available. Engineering Materials Science friction stir welding HSLA-65 Type 310 stainless steel Type 304L stainless steel Hot torsion Testing
6	A Study of EAF Austenitic and Duplex Stainless Steelmaking Slags Characteristics Mostafaee, Saman January 2010 (has links) <p>The high temperature microstructure of the solid phases within the electric arc furnace (EAF) slag has a large effect on the process features such as foamability of the slag, chromium recovery, consumption of the ferroalloys and the wear rate of the refractory. The knowledge of the microstructural and compositional evolution of the slag phases during the EAF process stages is necessary for a good slag praxis.</p><p>In <strong>supplement 1</strong>, an investigation of the typical characteristics of EAF slags in the production of the AISI 304L stainless steel was carried out. In addition, compositional and microstructural evolution of the slag during the different EAF process stages was also investigated. Computational thermodynamics was also used as a tool to predict the equilibrium phases in the top slag as well as the amount of these phases at the process temperatures. Furthermore, the influence of different parameters (MgO wt%, Cr<sub>2</sub>O<sub>3</sub> wt%, temperature and the top slag basicity) on the amount of the spinel phase in the slag was studied. In <strong>supplement 2</strong>, a novel study to characterize the electric arc furnace (EAF) slags in the production of duplex stainless steel at the process temperatures was performed. The investigation was focused on determining the microstructural and compositional evolution of the EAF slag during and at the end of the refining period.</p><p>Slag samples were collected from 14 heats of AISI 304L steel (2 slag samples per heat) and 7 heats of duplex steel (3 slags sample per heat). Simultaneously with each slag sampling, the temperature of the slag was measured. The selected slag samples were studied both using SEM-EDS and LOM. In some cases (<strong>supplement 2</strong>), X-ray diffraction (XRD) analyses were also performed on fine-powdered samples to confirm the existence of the observed phases.</p><p>It was observed that at the process temperature and at all process stages, the stainless steel EAF slag consists mainly of liquid oxides, magnesiochromite spinel particles and metallic droplets. Under normal operation and at the final stages of the EAF, 304L steelmaking slag contains 2-6 wt% magnesiochromite spinel crystals. It was also found that, within the compositional range of the slag samples, the only critical parameter affecting the amount of solid spinel particles in the slag is the chromium oxide content. Petrographical investigation of the EAF duplex stainless steelmaking showed that, before FeSi-addition, the slag samples contain large amounts of undissolved particles and the apparent viscosity of the slag is higher, relative to the subsequent stages. In this stage, the slag also includes solid stoichiometric calcium chromite. It was also found that, after FeSi-injection into the EAF and during the refining period, the composition and the basicity of the slag in the EAF duplex steelmaking and EAF stainless steelmaking are fairly similar. This indicates that, during the refining period, the basic condition for the utilization of an EAF foaming-slag praxis, in both austenitic and duplex stainless steel cases, is the same. Depending on the slag basicity, the slag may contain perovskite and/or dicalcium silicate too. More specifically, the duplex stainless steel slag samples with a higher basicity than 1.55 found to contain perovskite crystals.</p> EAF Slag Duplex steel 304L stainless steel Characterization Microstructural evolution Spinels Basicity Computational thermodynamics Slag foaming
7	A Study of EAF Austenitic and Duplex Stainless Steelmaking Slags Characteristics Mostafaee, Saman January 2010 (has links) The high temperature microstructure of the solid phases within the electric arc furnace (EAF) slag has a large effect on the process features such as foamability of the slag, chromium recovery, consumption of the ferroalloys and the wear rate of the refractory. The knowledge of the microstructural and compositional evolution of the slag phases during the EAF process stages is necessary for a good slag praxis. In supplement 1, an investigation of the typical characteristics of EAF slags in the production of the AISI 304L stainless steel was carried out. In addition, compositional and microstructural evolution of the slag during the different EAF process stages was also investigated. Computational thermodynamics was also used as a tool to predict the equilibrium phases in the top slag as well as the amount of these phases at the process temperatures. Furthermore, the influence of different parameters (MgO wt%, Cr2O3 wt%, temperature and the top slag basicity) on the amount of the spinel phase in the slag was studied. In supplement 2, a novel study to characterize the electric arc furnace (EAF) slags in the production of duplex stainless steel at the process temperatures was performed. The investigation was focused on determining the microstructural and compositional evolution of the EAF slag during and at the end of the refining period. Slag samples were collected from 14 heats of AISI 304L steel (2 slag samples per heat) and 7 heats of duplex steel (3 slags sample per heat). Simultaneously with each slag sampling, the temperature of the slag was measured. The selected slag samples were studied both using SEM-EDS and LOM. In some cases (supplement 2), X-ray diffraction (XRD) analyses were also performed on fine-powdered samples to confirm the existence of the observed phases. It was observed that at the process temperature and at all process stages, the stainless steel EAF slag consists mainly of liquid oxides, magnesiochromite spinel particles and metallic droplets. Under normal operation and at the final stages of the EAF, 304L steelmaking slag contains 2-6 wt% magnesiochromite spinel crystals. It was also found that, within the compositional range of the slag samples, the only critical parameter affecting the amount of solid spinel particles in the slag is the chromium oxide content. Petrographical investigation of the EAF duplex stainless steelmaking showed that, before FeSi-addition, the slag samples contain large amounts of undissolved particles and the apparent viscosity of the slag is higher, relative to the subsequent stages. In this stage, the slag also includes solid stoichiometric calcium chromite. It was also found that, after FeSi-injection into the EAF and during the refining period, the composition and the basicity of the slag in the EAF duplex steelmaking and EAF stainless steelmaking are fairly similar. This indicates that, during the refining period, the basic condition for the utilization of an EAF foaming-slag praxis, in both austenitic and duplex stainless steel cases, is the same. Depending on the slag basicity, the slag may contain perovskite and/or dicalcium silicate too. More specifically, the duplex stainless steel slag samples with a higher basicity than 1.55 found to contain perovskite crystals. / QC 20110413 EAF Slag Duplex steel 304L stainless steel Characterization Microstructural evolution Spinels Basicity Computational thermodynamics Slag foaming Metallurgy and Metallic Materials Metallurgi och metalliska material
8	Effect of Semi-Solid Processing on Microstructural Evolution and Mechanical Behavior of Austenitic Stainless Steel Samantaray, Diptimayee January 2015 (has links) (PDF) In view of the significant advantages offered by semi-solid processing, such as reduction in number of intermediate processing steps and energy input, and the potential for improving component complexity, it is of paramount interest to develop indigenous technology for semi-solid forming of steels, especially nuclear grade steels. For adopting semisolid processing as an alternative method of manufacturing of steels, it is essential to study the amenability of the steel for the process, understand the fundamental mechanisms of micro structural evolution and evaluate the mechanical properties of the steel after processing. To achieve this goal, the present work attempts to appraise the amenability of a low-carbon variant of 18%Cr-8%Ni austenitic stainless steel (304L SS) for semi-solid processing. Among the many requirements of the feedstock in semi-solid processing, a key feature that makes it amenable for semi-solid processing is the unique microstructure containing solid spheroids in a liquid matrix, thereby enabling thixo-tropic behaviour in the alloy. To understand the micro structural evolution in the steel, during major steps of semi-solid processing (partial melting, soaking and solidification), several experiments are carried out by varying the key parameters such as temperature, soaking time and cooling rate. Experimental results are analyzed in details to specify the effects of these parameters on the microstructure of semi-solid processed steel. The analysis indicates different phase transformation sequences during solidification of the steel from its semi-solid state. On the basis of experimental results, mechanism for micro structural evolution during partial melting and subsequent solidification of 304L SS is proposed. The effect of soaking time on the size and shape of the solid globules is analyzed using the theory of anisotropic Ostwald ripening. The semi-solid processing parameters, such as soaking time and temperature, are found to have significant influence on the globule distribution, globule shape, ferrite distribution and dislocation density, which in turn govern the tensile behaviour and mechanical properties of the steel after processing. Semi-solid processed 304L SS exhibits lower yield strength, ultimate tensile strength and higher strain hardening in temperature range 303–873K compared to as-received (rolled and subsequently annealed) 304L SS. However, semi-solid processed steel shows higher uniform elongation and fracture strain compared to the as-received steel. A pronounced effect of semi-solid processing is also found on the high temperature plasticity and dynamic recrystallization pattern. This work demonstrates the amenability of 300 series austenitic stainless steels for semi-solid processing. The investigation provides the significant insight into the mechanism of micro structural evolution in austenitic stainless steels during semi-solid processing and the important information on the mechanical properties and plastic flow behavior of the semi-solid processed steel. The results give crucial inputs for the optimization of processing parameters for obtaining the desired property in the product, and also for deciding the potential industrial application of the process. Austenitic Stainless Steel Semi-Solid Stainless Steel Processing Semi-solid Processed 304L 304L Stainless Steel Semisolid Metal Processing SS 304L Mechanical Engineering
9	Analyses multi-échelles du comportement et la durée de vie d’aciers inoxydables 304L sous sollicitations cycliques avec pré-écrouissage / Multi-scale analysis of behavior and fatigue life of 304L stainless under cyclic loading with pre-hardening Belattar, Adel 11 February 2013 (has links) Le travail s’intéresse aux effets d’un pré-écrouissage cyclique axial ou en torsion sur le comportement cyclique et la durée de vie en fatigue sous sollicitation axiale à température ambiante d’un acier inoxydable austénitique 304L. Les essais cycliques séquentiels à amplitude de déformation croissante ou décroissante montrent que la courbe cyclique du 304L est non-unique. Cette caractéristique est liée à la persistance de l’état microstructural généré pendant les cycles d’amplitude de déformation maximale de la première séquence. En augmentant le nombre des séquences, l’acier 304L montre une tendance vers une courbe cyclique asymptotique, l’écrouissage semble se stabiliser. Des essais de fatigue sous chargement axial ont été réalisés sur des éprouvettes vierges ou pré-écrouies en traction-compression ou en torsion. Les durées de vie ont été sensiblement réduites pour les éprouvettes pré-écrouies. Ce phénomène est lié à la formation de structures de dislocations denses héritées de la phase de pré-écrouissage. Cependant, l’augmentation de l’amplitude de déformation en fatigue réduit l’effet du pré-écrouissage. / This study investigates the effects of loading history on the cyclic stress-strain curve and fatigue behavior of 304L stainless steel at room temperature. Tension-compression tests were performed ont the same specimen under controlled strain, using several loading sequences of increasing or decreasing amplitude. The results showed that fatigue life is significantly reduced by the previous loading history. A previously developed method for determining the effect of prehardening was evaluated. Microstructural analyses were also performed; the microstructures after preloading and their evolution during the fatigue cycles were characterized by TEM. The results of these analyses improve our understanding of the macroscopic properties of 304L stainless steel and can help us identify the causes of failure and lifetime reduction. Acier inoxydable 304 L Pré-écrouissage Courbe cyclique Chargement non proprotionnel Écrouissage cinématique Écrouissage isotrope Structure de dislocation 304L stainless steel Prehardening Cyclic curve Non proportional loading Kinematic cyclic hardening Isotropic cyclic hardening Microstructures
10	Microstructure Evolution in 304L Stainless Steel Subjected to Hot Torsion at Elevated Temperature Lu, Jian 19 September 2011 (has links) (PDF) The current study focus on investigating a relationship between processing variables and microstructure evolution mechanism in 304L stainless steel subjected to hot torsion. The Gleeble 3800 with Mobile Torsion Unit (MTU) is utilized in the current study to conduct hot torsion test of 304L stainless steel. Samples are rotated at 1100℃ in the shear strain rate range of 0.02s-1 to 4.70s-1 and the shear strain range of 0.5 to 4. Orientation imaging microscopy (OIM) technique is used to collect and analyze the microstructure. At low strains (≤1) and strain rate (0.02s-1), average grain size remains relatively constant, but the lengths of DSs and LABs increase within grains. These are characteristics of the dynamic recovery (DRV). With increasing strain and strain rate, the lengths of DSs, LABs and HABs increase, accompanied by the decrease of average grain size. Subgrains with HAB segments are observed. These are characteristics of continuous dynamic recrystallization (CDRX). At strain rates greater than or equal to 0.94s-1, the fraction of deformation texture is about 3 times higher than that of rotated cube texture. The average grain size increases relative to that at a strain rate of 0.20s-1, accompanied by the increase of twin length per area. This indicates that grain growth take place after CDRX. Sigma phase is not observed in the current study due to the lack of static recrystallization (SRX) and the higher cooling rate. Jian Lu friction stir welding FSW 304L stainless steel hot torsion dynamic recovery DRV dislocation structures DSs low angle boundaries LABs high angle boundaries HABs Mechanical Engineering

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